Configurational Isomerism in Bis(N-alkylsalicylaldiminato)nickel(II

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Inorg. Chem. 1995, 34, 4032-4040

Configurational Isomerism in Bis(N-alkylsalicylaldiminato)nickel(II) Complexes: The Equilibrium Planar == Tetrahedral and Its Effect on the Kinetics and Mechanism of Ligand Substitution Rainer Knoch, Horst Elias," and Helmut Paulusi Anorganische Chemie 111, Institut fur Anorganische Chemie, Technische Hochschule Darmstadt, Petersenstrasse 18, D-64287 Darmstadt, Federal Republic of Germany Received December 21. 1994@ A series of bis(N-alkylsalicylaldiminato)nickel(II) complexes Ni(XYsa1-R) = NiA2 with different combinations of substituents X (= rerr-butyl, isopropyl, isobutyl, NO>,Br), Y (= methyl, H), and alkyl groups R (= H, methyl, ethyl, n-propyl, isopropyl, n-butyl, isobutyl, rerr-butyl, neopentyl) were prepared and characterized by their vis1 near-IR absorption spectra and magnetic moments (XYsal-R = anion of N-alkyl-3-X-5-Y-salicylaldimine). X-ray structure analysis of Ni(3-tert-butyl-5-methylsal-Et)2(= C28H40N202Ni; monoclinic, P211c;a = 12.188(4), b = 11.455(4), and c = 18.852(6) A, p = 97.66(1)"; Z = 4;R , = 0.0367) and of the corresponding Zn(I1) complex (= C28&0N202Zn; monoclinic, C21c; a = 27.14(2), b = 13.17(1), and c = 18.30(2) A, ,f3 = 120.64(2)"; Z = 8; R, = 0.0357) confirms a distorted planar geometry of the NiN202 coordination core and tetrahedral coordination of the zinc. The equilibrium constants KI and K2 for the formation of the various pyridine adducts NiA2py and NiAy2py, respectively, were determined by spectrophotometric titration in acetone. Variable-temperature 'H NMR measurements led to the equilibrium constants Kp,,for the fast configurational isomerization of complexes NiA2 in organic solution according to NiA2 (planar) --L NiA2 (tetrahedral). Conventional and stopped-flow spectrophotometries were used to study the kinetics of displacement of the two bidentate ligands in NiA2 by tetradentate ligands H2B = Hzsalen (= N,N '-disalicylidene- 1,Zdiaminoethane), Hzsalpren (= N,N '-disalicylidene1,3-diaminopropane),and Hzsal(Me)zen (= N,N '-disalicylidene- 1,2-diamin0-2-methylpropane) in acetone solution. Ligand displacement follows second-order kinetics, rate = ~ H ~ B [ N ~ A ~ ] [For H ~ complexes B]. Ni(3-tert-butyl-5methylsal-R)2 and H2B = Hzsalen, rate constant kH,B spans from 3.75 x IO4 M-' s-' for R = methyl to 4.4 x M-' s-' for R = tert-butyl at 298 K. The activation entropy ranges from -52.5 J mol-' K-' for Ni(3isobutylsal-ethyl)2to - 138 J mol-' K-' for Ni(3-nitro-5-methylsal-isopropyl)2.The parameters K1, K2, Kp,r,and ~ H , B are governed by the bulkiness and specific combination of the various substituents X and alkyl groups R. The size of these parameters allows meaningful conclusions concerning the associatively controlled mechanism of ligand displacement.

Introduction

MA2

The 3d* metal center Ni(I1) offers a rich coordination chemism with a variety of coordination numbers and coordination geometries. An interesting stereochemical aspect is that, with several bidentate chelate ligands'.* such as N,N'-dialkyl2-aminotroponeimines, for example, Ni2+ ions form fourcoordinate complexes Ni(R2-ati)~,~ which are subject to a fast configurational change in solution. The planar diamagnetic isomer is in equilibrium with the tetrahedral paramagnetic isomer, and increasing steric demands of R shift the equilibrium toward the tetrahedral We have studied the kinetics of ligand substitution according to eqs 1 and 2 in a variety of systems (M = Cu, Ni; HA = salicylaldimine; HB = ,8-diketone; H2B = H2salen3)by explor-

' Fachbereich Materialwissenschaft, Technische Hochschule Darmstadt.

@Abstractpublished in Advance ACS Abstracrs, June 15, 1995. (1) Schumann. M.: van Hokum. A,: Wannowius, K. J.: Elias. H. Inorp. Chem 1982, 21 606 (2) (a) Holm. R H , Everett, G W , Jr , Chakravorty, A Prog Inorg Chem. 1966. 7, 83. (b) Holm, R. H., O'Connor, M.Ihid. 1971. 14. 241. (3) Abbreviations: Ni(Rz-ati)z = bis(N,Nf-diaIkyl-2-aminotroponeiminato)nickel(II); HIsalen = HIB' = N,N '-disalicylidene-l,2-diaminoethane; Ni(XYsal-R)? = bis(N-alkyl-3-X-5-Y-salicylaldiminato)nickel(11). substituents X, Y, and R, respectively, H = hydrogen, Me = methyl, Et = ethyl, n-Pr = 1-propyl, i-Pr = isopropyl, n-Bu = 1-butyl, i-Bu = 2-methylpropyl, r-Bu = ferr-butyl, neo-Pe = neopentyl; HIsalpren = H?B2 = N,N'-disalicylidene-l,3-diaminopropane;Hrsal(Mehen = HrB3 = N,N'-disalicylidene- 1,2-diamino-2-methylpropane. (4) Schumann, M.; Elias, H. Inorg. Chem. 1985, 24, 3187.

+ 2 HB =MB, + 2 HA

(1)

+ H2B * MB + 2HA

(2)

MA,

ing solvent effect^,^ substituent effects,6 the effect of steric hindrance and axial blocking,' stacking interactions,* chiral discrimination? and intermediate formation.l o It has been shown for reaction 3 that Hzsalen attacks only the planar configurational isomer of Ni(R2-ati)23,the tetrahedral one being Ni(R,-ati),

+ H,salen == Ni(sa1en) + 2 R,-atiH

(3)

kinetically inert.4 ( 5 ) (a) Elias, H.; Frohn, U.; van Inner, A,; Wannowius, K. J. Inorg. Chem. 1980, 19, 869. (b) Elias, H.; Reiffer, U.; Schumann, M.; Wannowius. K. J. Inorg. Chim. Acra 1981, 53, L65. (c) Elias, H.; Muth, H.; Niedemhofer, B.; Wannowius, K. J. J. Chem. Soc., Dalton Trans. 1981,

9, 1825. (d) Elias, H.; Frohn, U.; Giegerich, G.;Stenger. M.; Wannowius, K. J. J. Chem. Soc., Dalton Trans. 1982,s. 577. (e) Elias. H.; Wannowius, K. J. Inorg. Chim. Acra 1982, 64, L157. (f) Elias, H.: Muth, H.; Sahm, H.; Volz, H.; Wannowius, K. J. Inorg. Chim. Acta 1983, 68, 163. (6) Elias. H.; Hasserodt-Taliaferro. C.; Hellriegel, L.; Schonherr, W.: Wannowius, K. J. Inorg. Chem. 1985, 24, 3192. (7). (a). Knoch. R.: Wilk, A.: Wannowius, K. J.: Reinen, D.; Elias, H. Inorn. Chem. 1990, 29(19), 3799. (b) Segla. P.: Elias, H. Inorg. Chim.Aria 1988, 149, 259. (8) Busing. B.: Elias, H.: Eslick, I.; Wannowius, K. J. Inorg. Chim. Acra 1988,-150(2), 223. (9) Warmuth, R.; Elias, H. Inorg. Chem. 1991. 30, 5027. (10) Hoss, H.: Elias, H. Inorg. Chem. 1993, 32, 317.

0020- 166919511334-4032$09.0010 0 1995 American Chemical Society

Inorganic Chemistry, Vol. 34, No. 16, 1995 4033

Bis(N-alkylsalicylaldiminato)nickel(II) Complexes

Chart 1. Structural Formulas of the Complexes and Ligands and Abbreviations3

Y-

Ni(XYsa1-R)2

.n .

H~salen= H2Bl

/=N

+ 2py === Ni(sal-R),(py) + py F=K2 Kl

NW-R),(py), (4) tetrahedral distortion occur for large R groups interacting with the neighboring phenolic oxygen andor large X substituents. It was therefore decided to use the combination of bulky X substituents and sterically more or less demanding R groups to prepare a series of complexes Ni(XYsa1-R);?with a variable degree of tetrahedral distortion. The size of the constant Kp,f, which can be obtained from the temperature dependence of the paramagnetic shift of the 'H NMR spectra of Ni(XYsa1-R)2, is a measure of the equilibration in solution according to eq 5 . Ni(XYsal-R), Kp.i Ni(XYsa1-R), planar (S = 0) tetrahedral (S = 1)

-

(5)

The kinetic parameters describing ligand substitution in acetone solution according to eq 6 were determined for the tetradentate ligands H2B = HzBI, H2B2, and H2B3 (see Chart 1) reacting with the complexes Ni(XYsal-R), listed in Chart 1. Ni(XYsa1-R),

+ H2B - NiB + 2 H-XYsal-R

Y

R

rBu

Me

iPr iBu NO2 Br

H Me Me

H, Me, Et, nPr, iPr, nBu, iBu, tBu, neoPe Et, iPr Et, iPr Et, iPr Et, iPr

(6)

The rate data obtained are compared to the thermodynamic parameters Kp,trK1, and K2 in order to correlate reactivity and state of coordination.

Experimental Section Ni(CH3COO)y4H20, NiBrl, Zn(CH3CO0)2*2H20, and the solvent acetone were reagent grade. The various amines and diamines used for the synthesis of the aldimines H-XYsal-R and salen-like ligands H2B by condensation with the corresponding aldehydes (1 1) Sacconi, L. Transition Metal Chemistry; Marcel Dekker, Inc.: New York, 1968; Vol. 4.

H

n N T

H~salpren= H2B2

The present contribution extends the study of configurational isomerism and its kinetic implications to substituted bis(Nalkylsalicylaldiminato)nickel(II) complexes (Ni(XYsa1-R)z), for some of which the equilibriumplanar * tetrahedral was reported For X = Y = H and R is small, complexes Ni(XYsal-R)z prefer the planar trans-Nz02 coordination geometry (see Chart 1) and tend to become octahedral in the presence of bases such as pyridine (see eq 4). It follows from model considerations that steric repulsion and, as a consequence, Ni(sa1-R),

X

.

.

H~sal(Me)aen= H2B3

+ R-NH, -H-XYsal-R + H 2 0 2H-XYsal f diamine - H2B + 2 H 2 0

H-XYsal

(7a)

(7b)

H-XYsal according to eqs 7a and 7b, respectively, were commercially available. The substituted ~alicylaldehydes~H-t-BuMesal,Iz H-iPrHsal,I3 H-i-BuHsal,I3 H-N02Mesal,I4J5 and H-BrMesal16 were prepared according to published procedures. Except for H-t-BuMesal-H, H-t-BuMesal-Me, and H-t-BuMesal-Et, Schiff base formation according to eq 7a was carried out in ethanol with stoichiometric amounts of aldehyde and amine RNHz at 60 OC. After evaporation of the solvent, the residue was dissolved in chloroform, dried with Na2S04, and taken to dryness to obtain the Schiff bases as yellow oils. They were used for complex formation without further purification. The preparation of the solid tetradentate ligands H2B', H2B2, and H2B3 according to eq 7b was described r e ~ e n t l y . ~ Complexes. Complexes Ni(t-BuMesal-H)?, Ni(t-BuMesal-Me)*, and Ni(t-BuMesal-Et)z were prepared in a one-pot reaction by adding an excess of an aqueous solution of the amine (NH3, MeNH2, and EtNH2, respectively), 5 mmol of Ni(CH3COO)y4HzO, and 10 mmol of sodium acetate to the solution of 10 mmol of H-t-BuMesal in 60 mL of ethanol, refluxing, and cooling, whereupon crystallization occurred. The same procedure was applied for the preparation of Ni(NOzMesal-R)z (R = Et, i-Pr), Ni(BrMesal-R)2 (R = Et, i-Pr), Zn(t-BuMesal-Et)*, and Zn(i-PrHsal-Et)z from the corresponding salicylaldehydes, amines, and metal salts, with methanol being the solvent. The general route leading to complexes Ni(t-BuMesal-R)2 (R = n-Pr, i-Pr, n-Bu, i-Bu, t-Bu, neo-Pe), Ni(i-BuHsal-R)z (R = Et, i-Pr), and Ni(i-PrHsal-R)z (R = Et, i-Pr) was the following. A solution of 20 mmol of the corresponding Schiff base H-XYsal-R, 10 mmol of NiBrz. and 100 mmol of Et3N in 100 mL of acetonitrile was mildly refluxed for 2-3 days, cooled, and filtered. The filtrate was taken to dryness and the residue was extracted with cyclohexane or petroleum ether (bp 40-80 "C), which was then dried with Na2S04 and cooled for crystallization of the complex. Petroleum ether was used for recrystallization, with tert-butylamine being added in the case of Ni(tBuMesal-t-Bu)2. The mixed complex [Ni(t-BuMesal-Et)~][Zn(t-BuMesal-Et)~]~ was obtained by slow evaporation of an acetone solution of 0.2 mmol of Ni(t-BuMesal-Et)l and 0.8 mmol of Zn(t-BuMesal-Et)2 at ambient temperature. The residue consisted of brownish crystals of the mixed complex (main component) and, as impurity, yellowish crystals of excess Zn(t-BuMesal-Et)2, which were separated under the microscope. (12) Ligett, R. W.; Diehl, H. Proc. Iowa Acad. Sci. 1945, 52, 191. (13) Casiraghi, G.; Casuati, G.; Puglia, G.; Sartori, G.; Terenghi, G. J. Chem. SOC., Perkin Trans. Z1980, 1862. (14) Borsche, W. Chem. Eer. 1917, 50, 1339. (15) Schotten, C. Chem. Eer. 1878, 11, 784. (16) Adams, R. J. Am. Chem. Soc. 1919, 41, 268.

4034 Inorganic Chemistry, Vol. 34, No. 16, 1995

Knoch et al. Table 1. Crystallographic Data for Complexes Ni(f-BuMesal-Et)?

4900

and Zn(t-BuMesal-Et)]

3900

1900

t t'

CrsH4oNlOrNi 495 35 P21lc 12.188(4) I 1.455(4) 18.852(6) 97 66(1) 2609(2) 4 24 1.27 7.78 0.0406 0.0367

CzsHjoN?OzZn 502.01 c21c 27.14(2) 13.17(1) 18.30(2) 120.64(2) 5627( 10) 8 23 1.19 8.9 1 0.0395 0.0357

P,

-100 0.002

I

0.003

b I

I

0.004

0.005 1J-rr1ncl Figure 1. Temperature dependence of the chemical shift of the 4-H resonance for the complex Ni(t-BuMesal-Et)2 in CzDzC14.

The ratio Zn/Ni in the mixed complex was found to be 3.1 by X-ray fluorescence analysis. The results of elemental analysis were in good agreement with the calculated data (see Table S1 in the supporting information). Instrumentation. UV/vis spectra: diode array spectrophotometer (Hewlett-Packard, type 845 1A). Near-IR spectra: double beam spectrophotometer (Zeiss, type DMR-21). IH NMR spectra: FT-NMR spectrometer (Bruker, type AC 300, 300 MHz). Magnetic susceptibility: magnetic susceptibility balance (Johnson-Matthey, type MSBMKI). Slow kinetics: double beam spectrophotometer (Perkin-Elmer, type 554). Fast kinetics: modified5a stopped-flow spectrophotometer (Dur", D 110). Equilibrium Constants for Adduct Formation. Equilibrium constants K I and K2 for pyridine addition according to eq 4 were determined by spectrophotometric titration. The Abs/[py] data (Abs = absorbance) were computer-fitted to eq 8.' The symbols Abs(NiAz), Abs(NiAypy), and Abs(NiAy2py) refer to the absorbance of the three species involved at [Nil,,,.

Abs = Abs(NiA,)

Zn(t-BuMesal-Et)zl

chemical formula form wt, g mol-' space group a, A b. 4 c, A

2900 zl

INi(r-BuMesal-Et)?l

+ Abs(NiA,py)K, [py] + Abs(NiA2-2py)K,K2[pyI2 1 + K,[PYl+ KIK*[PYI2

V,A 2

T, "C g(calcd), g cm-' p , cm-I R (Fo)" R,(Fdb

R,(F,) = x w 1 " ( F , - FJ~K"~F,,. "R(F,,) = )3(1Foi - /Fcl)/x~Fo~.

Table 2. Atomic Parameters for the Coordination Core of Complexes Ni(t-BuMesal-Et)2 and Zn(f-BuMesal-Et)? atom

xla

Nil 01 NI 02 N2 Znl 01 N1 02 N2 I'

ueq=

0.4068(0) 0.2717(1) 0.4814(2) 0.5433(1) 0.3313(2)

y/b dc Ni(r-BuMesal-Et)z 0.0140(0) 0.2882(0) 0.0213(1) 0.2294(1) -0.0457(2) 0.2133(1) 0.0484( 1) 0.3396(1) 0.0289(2) 0.3692(1)

0.0367(02) 0.0416(10) 0.0387(12) 0.0421(09) 0.0421(13)

0.2764(0) 0.2030(1) 0.3204(1) 0.3102(1) 0.2796( 1 )

Zn(f-BuMesal-Et)? 0.5057(0) 0.2371(0) 0.4770(2) 0.2226(1) 0.4670(2) 0.3596(2) 0.4544(2) 0.1752(1) 0.6507(2) 0.2087(2)

0.0479(02) 0.0421(14) 0.0551(19) 0.0573(15) 0.0619(20)

'/?(U,1+ U??

+ U??).

10-fold excess of HrB) at a suitable wavelength in the range 440-710 nm. Equation 10 (irreversible first-order reaction) was computer-fitted to the Abslf data obtained. Some experiments were carried out under

Abs = (Abs, - Abs,)[exp(-k,,,,t)l

(8) 'H NMR Measurements. The details of the 'H NMR investigation of the configurational equilibrium eq 5 have been described recently.' The spectra of complexes Ni(XYsal-R)z in C2D2C14 were recorded in the temperature range 233-393 K (standard (CH&Si). In the case of Ni(t-BuMesal-n-Pr)z the solvent was acetone-& and the range was 193313 K. The paramagnetic band shift, Av, is a direct measure of the fraction of the tetrahedral (paramagnetic) isomer present in solution4 and follows the relationships in eqs 9a and 9b. Least-squares fitting

+

Av = Avdia CT-'K,,,(l iKp,,)-l

of eq 9b to the experimentally obtained data for Av(T) led to the parameters C, AH,,?, and ASp,? (the value for Avdla was taken from the diamagnetic reference complexes Zn(r-BuMesal-Et)2 and Zn(iPrHsal-Et)z or from the corresponding free ligands H-XYsal-R). For each complex, the evaluation of these parameters was done for the resonance signal of three to four different protons (preferentially: -HC=N;-HC=NCH2-; aromatic 4-H, 5-H, or 6-H; 2-C(CH3)?; 5-CH3), and the results were averaged. Figure 1 demonstrates the temperature dependence of the 4-H resonance for the complex Ni(rBuMesal-Et)z. Kinetic Measurements. Reaction 6 was followed by conventional spectrophotometry (slow substitution) or by stopped-flow spectrophotometry (fast substitution) under pseudo-first-order conditions (at least

Ueq(i

+ Abs,

(10)

stoichiometric conditions ([complex] = [H2B]), and eq 11 (irreversible second-order reaction) was fitted to the data. The programs used were based on the least-squares method.

Abs = Abs,

+ (Abs, - Abs,)/( 1 + [complex],kt)

(1 1)

X-ray Structure Determination. Crystals of Ni(t-BuMesal-Et)? (greenish brown) and Zn(t-BuMesal-Et)z (pale yellow) were grown as short prisms from petroleum ether and methanol, respectively. The crystals chosen for X-ray measurements had the dimensions 0.16 x 0.45 x 0.7 mm (Ni(f-BuMesal-Et)2) and 0.32 x 0.35 x 1.0 mm (Zn(r-BuMesal-Et)z). Intensities were measured on a four-circle diffractometer (Stoe-Stad:-4) using graphite-monochromatized Mo K a radiation (3, = 0.71069 A: scan 20:w = l : l ) . Cell constants were determined on the same instrument by the least-squares method from the 20 angles of 66 (Ni(f-BuMesal-Et)?, T = 296 K) and 48 reflections (Zn(tBuMesal-Et)2, T = 295 K), respectively. LP and background corrections and a numerical absorption correction (SHELX-76) were applied. The structure was solved by direct methods with SHELXS-86 and refined by least-squares to the R values given in Table 1. Hydrogen atoms were positioned geometrically (C-H distance = 1.08 A) and not refined. An empirical extinction correction was applied. All crystallographic calculations were performed with the programs SHELX-76 and SHELXS-86 on an IBM 3081K computer at the Technische Hochschule Darmstadt. Scattering factors fo, f'and f"for C, H, N. and 0 are stored in SHELX-76. The final positional parameters are given in Table 2. (Data for Ni and Zn were taken from Infernational Tables for X-ray Cnstallography: Kynoch Press: Birmingham, England. 1974: Vol. IV.)

Inorganic Chemistry, Vol. 34, No. 16, 1995 4035

Bis(N-alkylsalicylaldiminato)nickel(II) Complexes

Table 3. Visible and Near-IR Absorption [A,,,, nm (cmax.M-I cm-’)l of Complexes Ni(XYsal-R)z in Acetone (visible) and Carbon Tetrachloride (Near-IR) and Magnetic Moments at 298 K complex Ni(t-BuMesal-H)z Ni(t-BuMesal-Me):! Ni(t-BuMesal-Et)2 Ni(t-BuMesal-n-Pr)2 Ni(t-BuMesa1-i-Pr)l Ni(t-BuMesal-n-Bu)* Ni(t-BuMesal-r-Bu)2 Ni(t-BuMesal-t-Bu)2 Ni(t-BuMesal-neo-Pe)z Ni( i-PrHsal-Et)2 Ni(i-PrHsal-i-Pr)z Ni(i-BuHsal-Et)2 Ni(i-BuHsal-i-Pr):! Ni(NO*Mesal-Et)* Ni(N02Mesal-i-Pr)z Ni(BrMesal-Et)2 Ni(BrMesa1-i-Pr):!

visible 420 (5200), 438s (4530), 570 (126) 396 (4720), 410s (4580), 654 (169) 384 (6720), 424s (4190), 660 (130) 388 (5800),420s (4580), 652 (139) 382 (10280), 430s (4270), 586s (148), 708 (96) 390 (5440). 418s (4470), 654 (145) 396 (5320), 416s (4810), 648 (165) 382 (10700), 428s (5280). 548 (291), 604s (186), 712 (66) 398 (5760), 420s (4680), 642s (145) 412 (5030), 518s (115), 632 (95) 368 (8420), 412s (4095), 510s (192), 578s (116), 700 (76) 414 (4560), 512s (1 13), 636 (83) 370 (7370), 412s (3540), 516s (197), 572s (124), 702 (82) 430 (10790), 606 (89) 422 (1 1310). 608s (74), 700s (41) 418 (5220), 620 (135) 382 (7720), 418s (5050),514s (194), 602s (99), 686s (63)

Ni(t-BuMesal-Et):!/Zn(t-BuMesal-Et)z (1 :3)

U

Ni(sa1en) Ni(sa1pn) Ni(sal(Me)2en)

412 (6660), 450s (3160), 550s (160) 416 (5070), 710s (67) 412 (6850), 442s (3690), 546s (158)

a

near-IR

kff,

PB

‘0.2 1400 (7.5) 1410 (28) 1410 (14) 1520 (71) 1400 (19) 1410 (11) 1700 (45) U

a a

a a

a a a

a a

>lb >>lb

13.7 f 2.8 7.9 f 1.6

0.004 f 0.001 0.04 f 0.01

Deuterated l11,2,2-tetrachloroethane.Complex is predominantly tetrahedral in the temperature range studied. Due to KP.(>> 1, relationship 9a takes the form Av = Avdia CTT (Curie behavior).

+

respectively. One should keep in mind, however, that complexes Ni(t-BuMesal-i-Pr)z and Ni(t-BuMesal-t-Bu)2 are the most tetrahedral ones within the series Ni(t-BuMesal-R);! studied. For these two complexes, Kp,i >> 1, so that relationships 9a and 9b are no longer useful for the determination of Kp.t (see Table 6). The overall result for complexes Ni(t-BuMesal-R)2 is that the organic group R increases the size of Kp,f according to neo-Pe

i-Bu < n-Bu < Et 0.05-0.1 M. In the concentration range studied, the dependence kobsd = JI[H2B]) was linear (see Figure 4).

4040 Inorganic Chemistry, Vol. 34, No. 16, 1995

Knoch et al.

group makes the nickel center a better Lewis acid and thus favors adduct formation.

such as salen is monophasic and follows second-order kinetics.

+ H,B -NiB + 2HA ~

Conclusions

NiA,

Sterically demanding X substituents and R alkyl groups force bis(N-alkyl-X-salicylaldiminato)nickel(II)complexes Ni(Xsa1R)2 = NiA2 to leave the preferred planar trans-N202 coordination geometry and become more or less tetrahedrally distorted. In organic solution, there is a fast configurational change according to equilibrium a. The equilibrium constant Kp.r, the size of

H

~

B

(c)

The effect of specific combinations of X and R on the size of (= K I K ~ )Kp,r, , and rate constant ~ H provides ~ B convincing evidence that ligand replacement according to equilibrium c is initiated by nucleophilic addition of H2B to planar NiA2 and formation of the adduct NiAyH2B. Loss of the first bidentate ligand HA is rate-determining.

Y

NiA,(planar,S = 0) "pi NiA,(tetrahedral,S = 1)

(a)

which is determined by the bulkiness of X and R, is obtained from variable-temperature 'H NMR measurements. In addition to equilibrium a, complexes NiA2 tend to add bases such as pyridine according to equilibrium b. Ligand substitution in NiA,(planar)

+ 2py ==

Kl

NiA2py

+ py ==

K2

NiA2*2py (b)

acetone according to reaction c with tetradentate ligands H2B

Acknowledgment. Sponsorship of this work by the Deutsche Forschungsgemeinschaft, Verband der Chemischen Industrie e.V., and Otto-Rohm-Stiftung is gratefully acknowledged. Salicylaldehyde was kindly provided by Bayer AG. Supporting Information Available: Tables of analytical data, crystallographic data, complete bond distances and bond angles, atomic positional parameters and anisotropic thermal parameters ( 14 pages). Ordering information is given on any current masthead page. IC941454Y